Method and apparatus for controlling a vehicle computer model with oversteer

ABSTRACT

A simulation system ( 30 ) for simulating an operation of an automotive vehicle includes an input ( 34 ) providing vehicle information and path information and a controller ( 38 ) having a vehicle computer model therein. The controller ( 38 ) is programmed to determine an initial steering wheel angle input to the compute model, determine a first steering wheel angle input to the computer model at a time later than the initial steering wheel angle input by comparing a look ahead point and an intended path, when the vehicle model is understeering, operate the computer model with the initial steering wheel angle input until an error of the first steering wheel angle and the initial is decreasing, when the error decreases, operate the computer model with the first steering wheel angle input; and generate an output in response to the vehicle model and the initial steering wheel input or the first steering wheel input.

CROSS REFERENCE TO RELATED APPLICATIONS

The present invention is related to U.S. Applications (Attorney Docket No. 202-1463/FGT-1890) entitled “Method And Apparatus For Controlling A Vehicle Computer Model In An Aggressive Limit-Seeking Manner”, and (Attorney Docket No. 202-1479/FGT-1889) entitled “Method And Apparatus For Controlling A Vehicle Computer Model With Understeer”, filed simultaneously herewith.

BACKGROUND OF INVENTION

The present application relates generally to computer models that test the dynamics of an automotive vehicle, and more particularly, to a method for operating a vehicle model in an aggressive or limit-seeking manner with oversteer.

In the development of automotive vehicles, computer vehicle models are often used to test various designs. The various designs may be used to efficiently assess the handling of the vehicle using various parameters.

Current algorithms for computer driving control of computer vehicle models are designed to efficiently follow a given path. That is, the given path is accurately followed to provide minimal loss of speed due to side slipping of the computer vehicle model. Typically, such systems use a simulated look ahead of a driver to determine whether the vehicle is on the desired path. This is illustrated in step 10. In step 12 it is determined whether or not the vehicle is on target or on the desired path. If the computer vehicle model is on the desired path, step 14 is executed in which no change in the steering wheel angle is provided. The system then continues to step 16 in which the next time increment of the model is provided.

Referring back to step 12, if the vehicle is not on its intended path or “on target”, step 18 is executed in which a new steering wheel angle (SWA) based on the size of the error between the look ahead path and the intended path is determined. In step 20 the computer model responds to the new steering wheel angle.

One problem with current computer vehicle models is that they are not typically designed to test the limits of control of the vehicle.

It would be desirable to be able to test the vehicle at aggressive or limit-seeking driving conditions. Typically, the computer model produces undesirable results that do not simulate real world driving when pushed to its limits. Typically, computer models generate undesirable steering wheel angles to compensate for variations in the desired path. The results are therefore not usable in the assessment of vehicle handling for such events. Therefore, it would be desirable to provide meaningful results when the vehicle model is driven aggressively, driven with understeer or oversteer.

SUMMARY OF INVENTION

The present invention allows a vehicle computer model to be driven near its limits to allow vehicle designers to assess the vehicle handling.

In one aspect of the invention, a method of operating a vehicle computer model having vehicle information and path information therein includes determining a plurality of current steering wheel angle inputs to the computer model by comparing a look ahead point and an intended path at various times, determining when the vehicle model is understeering in response to a yaw acceleration, when the vehicle model is understeering, holding the steering wheel angle to a first steering wheel angle input of the plurality of current steering wheel angles until an error determined as a function of the plurality of steering wheel angle inputs is decreasing, and when the error decreases, operating the computer model with the one of the plurality of current steering wheel angle inputs subsequent to the first steering wheel angle input.

In a further aspect of the invention, a simulation system for simulating an operation of an automotive vehicle includes an input providing vehicle information and path information and a controller having a vehicle computer model therein. The controller is programmed to determine an initial steering wheel angle input to the compute model, determine a first steering wheel angle input to the computer model at a time later than the initial steering wheel angle input by comparing a look ahead point and an intended path, when the vehicle model is understeering, operate the computer model with the initial steering wheel angle input until an error of the first steering wheel angle and the initial is decreasing, when the error decreases, operate the computer model with the first steering wheel angle input; and generate an output in response to the vehicle model and the initial steering wheel input or the first steering wheel input.

One advantage of the invention is that useful information may be obtained from vehicle models to allow vehicle designers to assess various vehicle designs in various limit-seeking an aggressive maneuvers. This, advantageously, will reduce the overall costs of development of the vehicle. That is, if more accurate information can be obtained using vehicle models, fewer prototypes will be built to test various designs.

Other advantages and features of the present invention will become apparent when viewed in light of the detailed description of the preferred embodiment when taken in conjunction with the attached drawings and appended claims.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a flow chart illustrating the operation of a prior art vehicle computer model.

FIG. 2 is a block diagrammatic view of a simulation system for operating a vehicle model on a computer driven path.

FIG. 3 is a diagrammatic view of a vehicle on a simulated road illustrating various dynamic conditions.

FIG. 4 is a flow chart of a vehicle computer model in an understeering condition.

FIG. 5 is a flow chart illustrating a vehicle computer model in an oversteering condition.

FIG. 6 is a plot of a look ahead scale factor versus curvature.

FIG. 7 is a flow chart of a vehicle computer model in an aggressive driving situation using the look ahead scale factor of FIG. 6.

DETAILED DESCRIPTION

In the following figures a vehicle computer model is described. The computer model may be run on various types of computers, including main frames or personal computers. The present system, as described below, may be used in aggressive limit-seeking manners. The system may be used when the vehicle is in an understeering condition. Vehicle understeering occurs when the front of the vehicle is plowing. That is, understeering is when the vehicle does not respond to a change in the steering wheel angle.

Oversteering is when the rear of the vehicle fishtails or slips out laterally relative to the front of the vehicle.

Referring now to FIG. 2, a simulation system 30 is illustrated. Simulation system 30 has a computer 32 that has an input device 34 and an output 36 coupled thereto. Computer 32 may be various types of computers including a main frame computer or a personal computer or a network personal computer. Input device 34 may include various types of input devices for inputting various information such as a keyboard, a mouse or trackball, or other types of information such as complete files as in a CD-ROM or other information stored within a memory.

Output device 36 may include various types of output devices including a screen display, printer output or file outputs such as a disk drive or CD-ROM drive. Of course, various combinations of input devices 34 and output devices 36 may be used in various commercial embodiments.

Computer 32 includes a controller 38 that is used to control a simulation using vehicle model 40. Vehicle model 40 may be manually input or selectively input using various input devices 34. Information such as a desired path information 42 or vehicle information 44 such as dynamic control information may be input using at least one of the input devices 34. The input device 34 may also initiate the operation of the vehicle simulation and input the desired path or changes in the desired path.

The controller 38 generates an output that may be provided to output device 36. Output 46 may include various limits, handling, reactions to double lane changes or the like. The various information provided by output 46 may be used to assess the vehicle's handling in aggressive driving and limit situations.

In FIG. 3, a representation of a vehicle 50 on a road surface corresponding to a path 52 is illustrated. FIG. 3 may represent a screen display. However, in an actual simulation a screen display may not actually be used. FIG. 3 is intended to provide a visual representation of some of the variables used in the vehicle model as described below. For example, the vehicle has a steering wheel 54 that is controlled by the computer model to traverse the intended path. The steering wheel 54 thus has a steering wheel angle (SWA). Typically, the steering wheel angle is measured from zero to a plus or minus angular direction.

The path 52 has a curvature with a radius represented by R. The vehicle model also includes a look ahead point 58 that has a look ahead distance which is the distance that the model looks ahead in order to determine the desired steering wheel angle of the vehicle as will be described below. Also, as further described below, the look ahead distance may be variable as opposed to fixed as in prior art vehicle models.

Also illustrated is a longitudinal vehicle velocity V_(x) and a lateral vehicle velocity V_(y). The longitudinal vehicle velocity and lateral vehicle velocity may be measured at different points on the vehicle including the front and/or the rear. The side slip angle is the inverse tangent of the ratio of the lateral vehicle velocity and the longitudinal vehicle velocity.

Referring now to FIG. 4, a method of controlling a vehicle model in understeer is illustrated. In step 70 the driver model looks ahead to find the vehicle path. If the vehicle is “on target”, step 72 is executed. In step 72 the vehicle is “on target” if the vehicle will follow a desired path within the look ahead range. If the vehicle will follow the desired path based upon the steering wheel input and various other inputs to the vehicle, no steering wheel change is provided in step 74. In step 76 the time of the vehicle model is incremented and then step 70 is again executed. In step 78 a new current steering wheel angle (SWA_current) based on the size of the error between the look ahead point and the desired path is determined. In this step a previous or initial steering wheel angle is determined from a previous loop as will be described below. This step forms a plurality of periodically determined steering wheel angle values. If the vehicle is not under-steering step 82 is executed. In step 82 the vehicle response is determined. The vehicle response in this embodiment is determined by the yaw acceleration which is normalized by the steering wheel angle. Of course, those skilled in the art will recognize various types of vehicle responses may be used. In step 84 the vehicle response, such as the normalized yaw acceleration, is compared to a threshold. If the normalized yaw acceleration is greater than a threshold and the absolute value of the steering wheel angle from step 78 is not increasing, step 86 is executed in which the steering wheel angle computed in step 78 is used and the plowing condition flag is set to false. Then, step 76 is executed.

Referring back to step 84, if the normalized yaw acceleration is greater than a threshold and the absolute value of the new steering wheel angle is increasing, the plowing flag set to true in step 88 and the steering wheel angle hold value (SWA_hold) is set to the current wheel value determined in block 78. The system then continues to block 76.

Referring back to block 80, if the plowing flag is set to be true from a previous step, step 90 is executed. In step 90 it is determined whether the error between the intended path and the desired path is converging or being reduced. The error is determined as a function of the normalized yaw rate and the current steering wheel angle. More specifically, in step 90 the normalized yaw acceleration is compared to a threshold. If the normalized yaw acceleration is greater than the threshold and the difference of the SWA_hold and the SWA_current is less than a tolerance and the absolute value of the SWA_current is decreasing, the error is being reduced. If the error is not being reduced, step 92 is executed in which the steering wheel angle is held at the previous time step value. In step 90, if the error is being reduced as set by the above-mentioned conditions, the steering wheel computed for the current time step is used. Also, the plowing condition flag is set to false since the vehicle is no longer and minimally plowing at this point. That is, when the conditions in step 90 are true, the vehicle model is being brought back under control. As can be seen, the steering wheel angle is not allowed to be changed to provide an undesirable result as in previous models. Thus, the current SWA value is held (while being monitored in step 90) until the value when it is determined that the vehicle is plowing is reached.

Referring now to FIG. 5, a method for operating the vehicle model during understeer is illustrated. In step 100 a rear side slip angle is determined. As mentioned above, the side slip angle is determined as function of the lateral vehicle velocity and the longitudinal vehicle velocity. The present system compares the rear side slip angle to a threshold such as 15° as is used in the present invention. If the rear side slip angle is not above 15°, step 102 is executed in which no change to the look ahead distance of the vehicle model is performed. That is, an unscaled look ahead factor is used. The system continues in step 104 in which the vehicle model is operated with the look ahead path. In step 106 if the vehicle is on the look ahead path no steering wheel angle change is performed in step 108.

Referring back to step 106, if the vehicle is not on target, step 110 is executed in which a new steering wheel angle (SWA_current) is determined based on the size of the error between the look ahead point and the intended path. After step 108 and 110, step 112 is executed in which the next time increment is provided to the vehicle model. Referring back to step 100, if the rear side slip angle is greater than the threshold (which in this case is 15°), step 114 is executed. In step 114, the look ahead distance is increased by a scale factor (SF). In the present example, a scale factor is determined that is exponential in value. That is, the absolute value of the rear side slip angle (SSR) is multiplied by a constant such as 0.02. This scale factor will be multiplied by the look ahead distance to increase the look ahead distance of the vehicle model. The new look ahead distance is used in step 104 to find the path. By providing the increased look ahead distance, the vehicle computer model generates useful results.

Referring now to FIGS. 6 and 7, a method for controlling the vehicle model during aggressive maneuvers is illustrated. The look ahead scale factor is changed as the function illustrated in FIG. 6. That is, the look ahead scale factor is normally 1. However, during a straight driving condition, the look ahead scale factor is reduced to 62-½ percent or 0.625 of the nominal look ahead scale factor. The scale factor increases as a function of the curvature of the road. Thus, as the curvature of the path increases, the look ahead scale factor also increases. In the present example, the look ahead scale factor is directly proportional (has a slope corresponding) to the curvature of the path. However, those skilled in the art will recognize that various curves may also be used depending on the vehicle. It should be noted that the curvature changes as a function of a negative and positive curvature of the path.

In FIG. 7, step 120 computes the curvature of the intended path. In step 124, the function of FIG. 6 is used to compute the look ahead scale factor. In step 126 the driver model uses the look ahead scale factor to determine the path of the vehicle. In step 128 if the vehicle is on target no change in steering wheel angle is commanded for the computer model. After step 130, step 132 increments the system to the next time.

Referring back to step 128, if the vehicle is on target, step 134 is executed in which the current steering wheel angle is based on the size of the error between the look ahead point and the intended path. This keeps in mind that the intended path may have been increased or decreased by the look ahead scale factor in step 124. After step 134, step 132 is again executed.

As can be seen, the present invention allows the vehicle model to be controlled in various conditions such as understeering or oversteering and aggressive driving. This will allow vehicle designers to more quickly and readily determine how the vehicle handling reacts to various handling events.

While particular embodiments of the invention have been shown and described, numerous variations and alternate embodiments will occur to those skilled in the art. Accordingly, it is intended that the invention be limited only in terms of the appended claims. 

1. A simulation system for simulating an operation of an automotive vehicle comprising: an input providing vehicle information and path information; and a controller coupled to the input, said controller having a vehicle computer model therein, said controller programmed to, determine an initial steering wheel angle input to the computer model; determine a first steering wheel angle input to the computer model at a time later than the initial steering wheel angle input by comparing a look ahead point and an intended path; when the vehicle model is understeering, operate the computer model with the initial steering wheel angle input until an error of the first steering wheel angle and the initial steering wheel angle is decreasing; when the error decreases, operate the computer model with the first steering wheel angle input; and generate an output in response to the vehicle model and the initial steering wheel input or the first steering wheel input.
 2. A system as recited in claim 1 wherein the controller controls an output device in response to the vehicle model and the initial steering wheel input or the first steering wheel input.
 3. A system as recited in claim 1 wherein the computer model comprises a dynamic control model.
 4. A system as recited in claim 1 wherein said controller determines when the vehicle model is understeering in response to a yaw acceleration.
 5. A system as recited in claim 1 wherein said controller determines when the vehicle model is understeering in response to a yaw acceleration and an increasing steering wheel angle.
 6. A system as recited in claim 1 wherein said controller determines when the vehicle model is understeering in response to a yaw acceleration greater than a threshold and an increasing steering wheel angle.
 7. A system as recited in claim 6 wherein said controller determines an increasing steering wheel angle by comparing the initial steering wheel angle input to the first steering wheel angle input.
 8. A system as recited in claim 1 wherein said controller determines the error in response to a decreasing steering wheel angle.
 9. A system as recited in claim 1 wherein said controller determines the error in response to a decreasing steering wheel angle and the previous steering wheel angle and the first steering wheel angle input.
 10. A system as recited in claim 1 wherein said controller determines the error in response to a decreasing steering wheel angle and a difference of the previous steering wheel angle and the first steering wheel angle input.
 11. A system as recited in claim 1 wherein said controller determines the error in response to a decreasing steering wheel angle and a difference of the previous steering wheel angle and the first steering wheel angle input compared to a threshold.
 12. A method of operating a vehicle computer model having vehicle information and path information therein comprising: determining an initial steering wheel angle input to the compute model; determining a first steering wheel angle input to the computer model at a time later than the initial steering wheel angle input by comparing a look ahead point and an intended path; when the vehicle model is understeering, operating the computer model with the initial steering wheel angle input until an error of the first steering wheel angle and the initial is decreasing; and when the error decreases, operating the computer model with the first steering wheel angle input.
 13. A method as recited in claim 12 further comprising determining when the vehicle model is understeering in response to a yaw acceleration.
 14. A method as recited in claim 12 further comprising determining when the vehicle model is understeering in response to a yaw acceleration and an increasing steering wheel angle.
 15. A method as recited in claim 12 further comprising determining when the vehicle model is understeering in response to a yaw acceleration greater than a threshold and an increasing steering wheel angle.
 16. A method as recited in claim 15 wherein an increasing steering wheel angle is determined by comparing the initial steering wheel angle input to the first steering wheel angle input.
 17. A method as recited in claim 12 further comprising determining the error in response to a decreasing steering wheel angle.
 18. A method as recited in claim 12 further comprising determining the error in response to a decreasing steering wheel angle and the previous steering wheel angle and the first steering wheel angle input.
 19. A method as recited in claim 12 further comprising determining the error in response to a decreasing steering wheel angle and a difference of the previous steering wheel angle and the first steering wheel angle input.
 20. A method as recited in claim 12 further comprising determining the error in response to a decreasing steering wheel angle and a difference of the previous steering wheel angle and the first steering wheel angle input compared to a threshold.
 21. A method of operating a vehicle computer model having vehicle information and path information therein comprising: determining a plurality of current steering wheel angle inputs to the computer model by comparing a look ahead point and an intended path at various times; determining when the vehicle model is understeering in response to a yaw acceleration; when the vehicle model is understeering, holding the steering wheel angle to a first steering wheel angle input of the plurality of current steering wheel angles until an error determined as a function of the plurality of steering wheel angle inputs is decreasing; when the error decreases, operating the computer model with the one of the plurality of current steering wheel angle inputs subsequent to the first steering wheel angle input.
 22. A method as recited in claim 21 wherein determining a plurality of current steering wheel angle inputs comprises periodically determining the plurality of current steering wheel angle inputs.
 23. A method as recited in claim 21 wherein the yaw acceleration comprises a normalized yaw acceleration.
 24. A method as recited in claim 21 wherein the normalized yaw acceleration comprises a steering wheel angle normalized yaw acceleration.
 25. A method as recited in claim 21 wherein operating the computer model with the one of the plurality of current steering wheel angle inputs subsequent to the first steering wheel angle input comprises operating the computer model with the one of the plurality of current steering wheel angle inputs subsequent to the first steering wheel angle input that corresponds in time to a decreased error.
 26. A method as recited in claim 21 further comprising determining the error in response to a decreasing steering wheel angle.
 27. A method as recited in claim 21 further comprising determining the error in response to a decreasing steering wheel angle and the previous steering wheel angle and the first steering wheel angle input.
 28. A method as recited in claim 21 further comprising determining the error in response to a decreasing steering wheel angle and a difference of the previous steering wheel angle and the first steering wheel angle input.
 29. A method as recited in claim 21 further comprising determining the error in response to a decreasing steering wheel angle and a difference of the previous steering wheel angle and the first steering wheel angle input compared to a threshold. 